The Optical Internet Wavelength Division Multiplexing (WDM) and Lambda Switching Mario BALDI http://www.synchrodyne.com/baldi Opticalnternet - 1 Copyright: see page 2
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WDM: Wavelength Division Multiplexing Transmission of multiple light signals (wavelengths) on the same strand of fiber DWDM - Dense WDM More sophisticated more expensive CWDM - Coarse WDM Lower number of wavelengths cheaper Opticalnternet - 3 Copyright: see page 2
Initial WDM Application Increase transmission capacity of fiber Increase the utilization (ROI: return of investment) of [existing] fiber Point to point configurations Opticalnternet - 4 Copyright: see page 2
Interim WDM Application Add/drop multiplexing Ring topologies with WDM add/drop multiplexers Optical Add-Drop Multiplexer (OADM) Inserting wavelengths on the ring Extracting wavelengths from the ring Mostly static or semipermanent interconnection configurations Reconfigurable OADM (ROADM) Opticalnternet - 5 Copyright: see page 2
Add/drop multiplexing Interim WDM Application Core Rtr Gigabit Ethernet OC-48/192 POS ATM Sw OC-3/12, DS3 ATM ADM 10/100BT OC-3/12 POS Edge Rtr ATM Sw OC-48 ATM OADM OADM OC-48 ATM ATM Sw Metro DWDM Ring (OADMs) Edge Rtr Gigabit Ethernet OADM OADM OC-48/192 POS Edge Rtr OC-3/12, DS3 ATM ADM ADM 10/100BT OC-3/12 POS ATM Sw Edge Rtr Opticalnternet - 6 Copyright: see page 2
Ultimate WDM Application Wavelength switched networks Arbitrary mesh topologies of WDM links and wavelength switches A.k.a. wavelength routers, lambda routers, lambda switches Mostly ( only ) optical cross connects Optical Switching Wavelength switching Opticalnternet - 7 Copyright: see page 2
Wavelength Switching Opticalnternet - 8 Copyright: see page 2
What to do with Optical Switches? Optical Mesh SONET ADM Optical Switch SONET ADM = WDM Terminal = IP Router or ATM Switch Opticalnternet - 9 Copyright: see page 2
Optical Switching Fiber cross-connect the whole signal from an input fiber switched to an output fiber Micro-electro-mechanical systems (MEMS) Wavelength cross-connect without wavelength conversion one (or more) wavelengths from an input fiber to an output fiber WDM de-multiplexer+mems amplification before or/and after switching OEO (optical-electrical-optical) conversion with electrical regeneration optical amplification Optical core Opticalnternet - 10 Copyright: see page 2
Optical Switching Wavelength cross-connect with wavelength conversion one (or more) wavelengths from an input fiber to other one (or others) on an output fiber OEO (optical-electrical-optical) conversion with electrical switching easier signal monitoring forward error correction (FEC) possible to reduce Bit Error Ratio (BER) O/E Electrical core E/O Opticalnternet - 11 Copyright: see page 2
Dynamic Optical Switching Wavelength switch without wavelength conversion switch configuration is changed dynamically by management by time of day every packet!?! WDM de-multiplexer+mems, electroholography, bubbles Wavelength switch with wavelength conversion OEO (optical-electrical-optical) conversion with electrical switching circuit switching (SONET/SDH) Optical core O/E Electrical core E/O Opticalnternet - 12 Copyright: see page 2
l Switching: the N 2 Problem SEA 20 ls = N (N-1) N 2 CHI SF 5 ls NYC LA Opticalnternet - 13 Copyright: see page 2
Wavelength Conversion Complex OEO conversion expensive non data transparent does not scale Does not require the same wavelength endto-end No wavelength assignment problem N 2 problem Opticalnternet - 14 Copyright: see page 2
IP over Glass? Not Exactly Demand for Virtual Networks IP Fundamental Demand for Internet Applications ATM Demand for Ring Protection SONET/SDH Demand for Raw Bandwidth! Mesh restored OPTICAL Opticalnternet - 15 Copyright: see page 2
What is Expected from the Optical Network? Provisioning and protection of lightpaths end-to-end Client equipment (e.g. routers) to provision optical layer lightpaths Cost-effective deployment of flexible networks Opticalnternet - 16 Copyright: see page 2
Provisioning Step 1 -Request Bandwidth Optical Switch IP Router Step 2 - Provide New Channel Control Channel Opticalnternet - 17 Copyright: see page 2
Provisioning Step 5 - Release Bandwidth Step 6 - Disconnect Channel and Use Elsewhere IP Router Control Channel Opticalnternet - 18 Copyright: see page 2
Protection/Restoration Protection: pre-determined action non-optimal resource utilization Restoration: dynamically determined action optimization of resource utilization Step 4 - Restore Connection Step 3- Fiber Cut - Hold off Control Channel Opticalnternet - 19 Copyright: see page 2
Protection/Restoration Multiple levels of protection: Layer 1 optical, e.g. SONET-like Layer 2 data link bundle Layer 2.5 protected MPLS LSPs Layer 3 routing Can trigger multiple layers of restoration each has different timescales for detection and repair Must avoid: unnecessary traffic shifting packet loss, reordering, control plane churn pathological feedback non self-stabilizing Opticalnternet - 20 Copyright: see page 2
Signaling: What Optical Switches Need Resource discovery Topology Access points and node identification Resource usage Connection management Lightpath setup Lightpath take down Lightpath modification Mesh/ring network protection and recovery Distributed routing Establishment of protection service classes Opticalnternet - 21 Copyright: see page 2
Signaling: What Optical Users Need Resource discovery Address of users reachable through the optical network Manage lightpaths Lightpath setup Lightpath take down Lightpath modification Negotiate protection service classes Protected, unprotected, best effort lightpaths Does all this sound familiar? ATM Opticalnternet - 22 Copyright: see page 2
Signaling: How to Do It How is the optical layer controlled? Layer 3 control plane? MPLS/LDP? LSPs mapped over wavelengths OSPF, BGP4? New signaling and routing standards? Proprietary vendor specific? Out of band or in-band Ethernet control channel Opticalnternet - 23 Copyright: see page 2